Multiplying by the reciprocal is often a good approach, as you have noted though real numbers are not supported. You need to work with fixed point rather than floating point reals.

Verilog does not have a definition of fixed point, but it it just uses a word length and you decide how many bits are integer and how many fractional.

0.01 (0.0098876953125) in binary would be `0_0000001010001`

. The bigger this word length the greater the precision.

```
// 1Int, 13Frac
wire ONE_HUNDREDTH = 14'b0_0000001010001 ;
input a [15:0]; //Integer (no fractional bits)
output result [15+14:0]; //13 fractional bits inherited form ONE_HUNDREDTH
output result_int [15:0]; //Integer result
always @* begin
result = ONE_HUNDREDTH * a;
result_int = result >>> 13;
end
```

Real to binary conversion done using the ruby gem fixed_point.

A ruby irb session (with fixed_point installed via `gem install fixed_point`

):

```
require 'fixed_point'
#Unsigned, 1 Integer bit, 13 fractional bits
format = FixedPoint::Format.new(0, 1, 13)
fix_num = FixedPoint::Number.new(0.01, format )
=> 0.0098876953125
fix_num.to_b
=> "0.0000001010001"
```